Air conditioning system



April 1941- I a. D. BOW-ER 2. 37.306

AIR CONDITIONING SYSTEM v Filed Aug. 16, 1937 2 Shegts-Sheet 1 WINTER I OPEN CLOSED WINTER O N a INVENTOR (ie mrqje D. Bower ATTORNEY April 8, 1941. G. D. B WER 2,237,300 I AIR CONDITIONING SYSTEM Filed Aug. 16,1937 I 2 Sheets-Sheet 2 WINTER INVENTOR G0re 1 Bower ATTORN EY Patented Apr. 8, 1941 AIR, CONDITIONING SYSTEM George D. Bower, Columbia Heights, Minn., as-

signor to Minneapolis-Honeywell Regulator Company, Minneapolis, Minn., a corporation of Delaware Application August 16, 1937, Serial No. 159,309

10 Claims.

This invention relates to an air conditioning system, and more particularly to a system in which heated air or unheated air may be circulated through a space as conditions in said space require. Thus, in the winter time, heated air is circulated through a space when the temperature in the space falls below a predetermined value, whereas in the summer time it may be desirable to circulate unheated air through the space when the temperature rises above a predetermined value. ,In such systems, the air circulating means is preferably under the control of a temperature responsive device in the furnace or heater when heated air is desired to be circulated, so that when heat is desired in the space, the air circulating means will not be operated until the temperature of the heater reaches a certain value. It is desirable, when unheated air is to be circulated upon the attainment of a predetermined temperature in the space, to have the air circulating means operate independently of the temperature responsive means in the heater, so that no adjustment of this means is necessary.

It is therefore an object of my invention to provide an improved air circulating system for circulating heated or unheated air through a space as conditions require.

More specifically, it is an object of my invention to provide an air circulating system for automatically operating a fan to supply heat to a space to maintain a predetermined temperature in the space during cold weather, the air cir-- culating means being under the control of a temperature responsive device in the air heater, and during hot weather, to circulate unheated air through the space when the temperature reaches a predetermined value, the circulating means in this latter operation being independent of the temperature responsive device in the air heater.

Another object of my invention is to provide a summer-winter air circulating system, wherein a fan is operated in hot weather to circulate unheated air through a space whenever the temperature in the space reaches a certain value, and wherein, should the temperature in a heater rise to a certain high value for any reason during the summer, as when trash is burnedtherein, the fan will be operated to dissipate th heat from the heater thereby preventing the attainment of excessive temperatures in the heater.

A further object is to provide an air circulating system wherein, in cold'weather, aheater and a fan are under the control of a space thermostat, the fan being also underthe control of a thermostat in the heater, and wherein, in hot weather, the heat changing means may be removed from the control of the space thermostat and the fan may be automatically operated to supply unheated air to the space in response to the attainment of a predetermined temperature in the space, the fan during this time being operated independently of the thermostat in .the

heater. r

A further object is to provide an air circulating system wherein a two-speed fan is operated to circulate air through a heater and a space to be heated in cold weather, wherein the fan runs at low or high speed depending on th temperatures existing in the heater and the space, the heater being under the control of a space thermostat, and in which the fan is run at high speed in summer when the temperature of the spac reaches a predetermined value, the fan operation being independent of the temperature of the heater, the heater being rendered inoperative.

Further objects will become apparent upon a study of the specification, claims and appended drawings, in which similar reference characters represent similar parts in the two figures, and in which Figure 1 is a view of my air circulating system in which a single speed fan is provided, and

Figure 2 shows a view of my system utilizing a two-speed fan.

In Figure 1 I have shown a conventional warm air furnace represented by the reference character Ill, said furnace having warm air ducts II, a stack l2, a draft damper l3, a blower l4, and a firing door 22. r

A return air pipe l5 supplies air to the blower It, said blower being driven by a motor l6 having terminals l1 and I8, said motor being connected to the blower by means of a belt l9 passing over pulleys 20 and 2| of the fan and motor, respectively.

For operating damper l3, a damper motor 23 having terminals 24 and 25 is provided. An arm 26 is caused to move upwardly against a stop 21 when the motor is energized, this arm being con-' nected to damper 13 by means of a cable 28 passing over a pulley 29, whereby the damper I3 is caused to open and remains open as long as the damper motor is energized. When the motor is deenergized, the weight of damper l3 will cause arm 26to move against stop 36 in which position the damper is closed. 'Aspring 31 may be pro-' vided to assure the return of arm 26to the damper closing position. r I

Mounted in "a space to beconditionedis a thermostat generally indicated by reference char.

acter 30. This thermostat comprises a bimetallic element 3| .to which are connected blades 32 and 33 to be moved thereby in response to temperature changes in the space. Cooperating with blades 32 and 33 are fixed contacts 34 and 35, contact 34 being positioned closer to blade 32 than is contact 35 with respect to blade 33. Blade 32 is made flexible, the arrangement being such that when the temperature drops to a certain value,

blade 32 will engage contact 34 and when the temperature drops to a slightly lower, value blade 33 will engage contact 35.

For controlling the operation of the blower l4 and the damper motor 23, I have provided a relay generally indicated by the reference character 48. This relay comprises a coil 4|, an armature 42, a switch blade 43 cooperating with a fixed contact 44, a switch blade -45 cooperating with fixed contact 46 and a switch blade 41 cooperating with contacts 48 and 49. When the relay is deenergized, blades 43, 45, and 41are out of engagement with contacts 44, 46, and 48, respectively, and blade 41 is in engagement with contact 49, and upon energization of coil 4 the switch blades 43, 45, and 41 are all moved into engagement with contacts 44, 46, and 48, respectively.

Mounted in the heating chamber of furnace I is a bimetallic element 60 connected at one end with a rod 6|, said rod being connected with mercury switches 62 and 63 to tilt the same in response to temperature changes in the heating chamber in a well known manner. Mercury switches 62 and 63 are provided with mercury elements 64 and 65. Switch 62 is provided with contacts 66 and 61 which are normally closed by the mercury element 64, said switch being tilted in response to the attainment of a predetermined high temperature in the heating chamber. to open contacts 66 and 61. Switch 63 is provided with contacts 68 and 69, these contacts being normally open and being closed by the mercury element 65 when said switch is tilted in response to the at-- tainment of a predetermined high temperature, the temperature necessary to tilt switch 63 to closed position being less'than that necessary to Operation of species of Figure 1 With the parts in the position illustrated, manual switch 50 is in engagement with contact and switch 52 is out of engagement with contact 53, these being the positions of the switches for winter operation. Blades 32 and 33 of thermostat 33, are out of engagement with contacts 34 and 35, respectively, the temperature in' the space in which thermostat 33 is located being sufllciently high so that no heat is required in the space. No current is flowing through motor l6 or motor 23, so that minimum heat is being supplied to the heating chamber and no air is being circulated by blower M in the space to be heated.

Assume that thetemperature in the space to be heated falls to a point where blade 32 of ther- R mostat 38 engages contact 34. No circuit is closed 7;,

by this action of the thermostat. If the temperature drops to a value slightly lower than that required to cause'thermostat blade 32 to engage contact 34, two degrees for example, the blade 33 of thermostat 38 will engage contact thus energizing a circuit through relay coil 4|, which circuit is as follows: from the low tension coil 14 of transformer 13 through conductor 88, contact 34, thermostat blades 32 and 33, contact 35, conductors 8| and 82, coil 4| and conductor 83 back to the other side of the low tension coil 14. Energization of coil 4| causes switch blades 43, 45, and 41 to engage contacts 44, 46, and 48, respectively. Engagement of switch blade 43 with contact 44 closes a holding circuit through the relay whereupon relay coil 4| will remain energized until both thermostat blades 32 and 33 have moved away from their respective contacts. Itv

will therefore be seen that relay coil 4| is energized at a temperature slightly lower than that at which it is deenergized. This holding circuit for coil 4| is as follows: from low tension coil 14 through conductor 80, contact 34, thermostat blade 32, bimetallic element 3|, conductor 84,

contact 44, switch blade 43, conductors 85, 82, re-

lay coil 4| and conductor 83 to the other side of low tension coil 14.

Movement of switch blade 45 intoengagement with contact 46 by the energizaition of coil 4| closes a circuit through damper motor 23, this circuit being as follows: from the line 10, through conductor 80, contacts 66 and 61 which are closed by the mercury element 64, switch 50, contact 5|, conductor 92, contact 46, switch blade 45, conductor 93, terminal 24 of motor 23, through the motor to terminal 25 and through conductor 84 to the line H. Energization of motor'23 causes damper l3 to be opened as previously described and the temperature in the heating chamber starts to rise.

When the temperature rises to a point wherein bimetallic element causes switch 63 to be tilted to a position wherein mercury element 65 closes contacts 68 and 69, a circuit through fan motor I6 is energized, this circuit being as follows: from the line 10 through conductor 98, contacts 69 and 68, conductor 98, contact 43, switch blade 41, conductor I00, terminal I! through the motor to terminal l8 and conductor |0| to the line 1| The motor now causes. operation of blower l4 whereupon the air is circulated through the heating chamber of furnace l0, warm air ducts through the space or spaces to be heated and back to the blower |4 through the return air duct 5. When the temperature in the space in which thermostat 30 is located, rises to a predetermined value, thermostat blades 32 and 33 are moved out of engagement with their respective contacts 34 and 35, thus causing thecircuit through relay coil 4| to be broken, whereupon blades 43, 45, and 4| move back to their original positions, thus causing motor 6 and motor 23 to be' deenergized whereupon the draft to the furnace is'cut oif and blower l4 comes to rest; This cycle of operation'will of course be repeated whenever the temperature in the space in which the 'thermo-' It is desired to circulate unheated air through the temperature of the heating chamber of the the spacein hot weather as in the summer time,

switch 50 will be moved out of engagement with contact 5| and switch 52 will simultaneously be moved into engagement with contact 53. The moving away of switch 50 from engagement with contact 5| opens the circuit through motor 23 so that the said motor is never energized regardless of the temperature in the space. With switch blade 52 in engagement with contact 53 and relay coil 4| deenergized by reason of the fact that the temperature in the space'is at a value higher than that required to cause blades 32 and 33 of thermostat 3| to engage their respective contacts 34 and 35, current will flow through the motor I6 as follows: from the line I0 through conductor I04, contact 53, switch blade 52, conductor I05, contact 43, switch blade 41, conductor I00, terminal I! of motor I6 through the motor to terminal I8 and conductor IM to line ll. It should be noted that this circuit through the motor is'independent of the mercury switch 63 so that the operation of the motor when the temperature in the space is above a predetermined value is not dependent upon the closing of contacts 68 and 69 of said switch 63.

Should the temperature in the space now drop to a point where thermostat blades 32 and 33 are moved into engagement with contacts 34 and 35 by reason of the circulation of unheated air through the space, relay coil M will be energized through the same circuit as that previously described. Energization of relay coil 4I now causes blade 41 to move out of engagement with contact 49 and into engagement with contact 48. Since switch 63 will normally be tilted to open position when the heating chamber of furnace I0 is unheated both of the previously describedcircuits through motor I6 are open and blower I4 is at rest. Blower I4 will not again be operated until the temperature in the space rises to a point wherein the blades 32 and 33 of the thermostat move out of. engagement with contacts 34 and 35', thus deenergizing relay coil M and allowing switch blade 41 to move into engagement with contact 49.

Should trash be thrown in the furnace I0 for the purpose of burning it up or for the purpose of temporarily supplying some heat to. the space during an unseasonable cold spell during the summer, the temperature in the heating chamber of the furnace will rise, and if it rises to a high enough value, switch 63 will be tilted .to. a positionwherein mercury element 65 closes contacts 68 and 69. Thus with the thermostat in the position with blades 32 and 33 in engagement with contacts 34 and 35, while the regular summer circuit through the motor I6 will be furnace, but the motor may be operated with the parts in summer position when the temperature of the space has fallen below the predetermined temperature should the temperature of the heating chamber. of the furnace be raised in any manner such as by the burning of trash therein. Thus is will be seen that in the summer time motor I6 will operate if the temperature in the heating chamber is above a predetermined value, regardless of the temperature in the space, and this is desirable to prevent the attainment of an excessive high temperature in the heating chamber.

Description of Figure 2 In the form of invention shown in Figure 2 a warm air furnace similar to that shown in Figure fixed contacts I and ISI.

1 is provided. A two-speed motor I I0 is provided in this instance for operating blower I4, this motor being of the split phase induction type and comprises an armature I I I, low speed field windings H3 and H4, and high speed windings II5 and H6. windings H4 and H6 are connected together at one end, this end being connected to line II through a condenser 1, whereas windings H3 and II5 are directly connected to the line II at one end thereof.

.For changing the flow of current from the low to the high speed windings and vice versa, a relay generally indicated by the reference character I20 is provided. This relay comprises a coil I2I, an armature I22 to which are connected switch blades I23 and I26, switch blade I23 being arranged to cooperate with fixed contacts I24 and I25 and switch blade I26 being arranged to cooperate with fixed contacts I21 and I28. When the relay coil I2I is deenergized the blades I23 and I26 are in the positions shown, in engagement with contacts I 24 and I21 and when said coil is energized the switch blades are moved into engagement with contacts I25 and I28.

The bimetallic element controls the operation of three mercury switches designated by reference characters I40, MI, and I42 having mercury elements I43, I44, and I45, respectively.

Switch I40 is provided with fixed contacts I46 and I41, switch MI is provided with fixed .contacts I48 and I49 and switch I42 is provided with Contacts I46 and I41 ofswitch 140 are normally closed whereas the contacts of the other two switches are normally broken by reason of relay coil 40 becoming energized and causing switch blade 4! to move out of engagement with contact 49, a circuit through the motor I6 will be established through the switch 63, this circuit being the same as that described in connection with'the winter operation of the circuit, it being understood, of course, that switch blade 41 has moved into engagement with contact 48.

It is thus seen that with the system just described the operation of the blower in the winter time is dependent upon the attainment of a certain temperature in the heating chamber of the furnace I0 but in the summer operation of the system the motor. I6 is caused to operate when the temperature in the space reaches a certain high-value, through a circuit which is en tirely independent of the switch responsive to the system shown inFigure 1. .Switch blades open. The switches are so arranged that when the temperature in the chamber of said furnace I0 reaches one value contacts I48 and I49 of switch I are closed, when the temperature rises to a certain higher value contacts I50 and I5I of switch I42 are closed and if the temperature rises to a still further high value; contacts I46 and I41 of switch I40 are opened.

A switch 50 cooperates with a contact 5I as in I 30 and I32 are also provided, these switches cooperating with contacts I3I and I33,respectively,

these switches being all manually operated. 'I-hese switches will in practice be grouped together and mostat 30 is satisfied, that is, it is not calling for any heat, damper I3 is closed and motor I I0 is deenergized. When heat is required in the space surrounding the thermostat 30, blades 32 and 33 move into engagement with contacts 34 and 35 thereby energizing relay coil 4| in the same way as in Figure 1. Switch blades 43, 45, and 41 are all moved into engagement with their respective contacts 44, 46,- and 49, the movement of switch blade 43 into engagement with contact 44 closing a holding circuit through the relay coil 4I which is independent of thermostat blade 33 as described in connection with Figure 1. Movement of switch blade 45 into engagement with contact 46 causes damper motor 23 to be energized as previously described whereupon the temperature in the heating chamber of furnace I commences to rise.

After the temperature has risen to a point in.

which mercury switch I4I has been tilted to close contacts I46 and I49, a low speed circuit through motor H0 is energized, this circuit being as follows: from line 10 through conductors 90, I51, contact I46, mercury element I44, contact I49, conductors I56 and I59 to the switch blade I26 and through conductor I63 to blade I23. From switch I26 current flows through winding II3 as follows: contact I21, through conductor I60, winding II3, conductors I6I and I62 to the line H. Current also flows through winding I I4 as follows: from the switch blade I23, contact I24, conductor I64 through winding II 4, condenser H1, and conductor I62 to the line H. The motor I I4 now starts operating at low speed to circulate air through the heating chamber of the furnace I0 and the space or spaces to be heated at a low rate of flow.

If the temperature of the heating chamber ment I45, contact I5I, conductor I, contact 49, switch blade 41, conductor I12, and coil I2I through conductor I13 to the line 1|. Energization of coil I2I causes switch blades I23 and I 26 to be moved into engagement with contacts I25 and I26, respectively. Current now flows to the switch blades from line 10, through conductors 90, I51, contact M6, mercury element I44, contact I49, conductors I56, I59, and through switch blade I26, contact I28, conductof'I15, high speed winding- I I5, conductors I16 and I62 to the line H. Current also flows from conductor I59 through conductor I63, switch blade I23 through contact I 25, conductor I11 through the high speed winding II6, condenser H1 and the conductor I62 to the line N. that with switch blades I23 and I26 in engagee ment with contacts I25 and I26 current flows through the high speed .motor windings whereupon the fan is rotated at high speed and causes It is therefore seen move into the positions illustrated. The moving of switch blade 45 out of engagement with contact 46 causes motor 23 to be deenergized whereupon the temperature of the heating chamber starts to drop. The moving of switch blade 41 out of engagement with contact 49 opens the above described circuit through the relay coil I2I circulation of air through the system at a high I rate of flow.

Should the temperature of the heating chamber rise to a value wherein switch I40 is opened before the space thermostat 30 is satisfied the blades 32 and 33 have moved out of engagementwith contacts 34 and 35, relay coil 4| is deenergized and the switch blades 43, 45, and 41 whereupon switch blades I26 and I23 are moved back to their original positions, the high speed circuit through'the motor is broken and the low speed circuit through the motor isreenergized, this low speed circuit being independent of relay coil H but dependent solely on closing of contacts I46 and I49 of switch I H. When the temperature in the heating chamber drops to a value in which this switch I is tilted back to open position the circuit through the motor H0 is interrupted and the motor and blower come to rest. The above described cycle of operation will be repeated when .there is again a call for heat by thermostat 30.

If it is desiredto change the system to summer operation to circulate unheated air through the space, switch blade 50 is moved out of engagement with contact 5I thus preventing'any circuit from being established through motor 23 and thereby preventing energization of said motor during summer operation. Switch blades I30 and. I32 are simultaneously moved into engagement with contacts I3I and I33. If thermostat 3| is in the position illustrated the temperature in the space is higher than that desired and unheated air will be circulated through the system. A circuit through relay coil I 2| is energized as follows: from the line 10 through conductor I60, contact I33, switch blade I32, conductor I9I, contact 46, switch blade 41, conductor I12, relay coil I2I, and conductor I13 to the line H. Switch blades I23 and I26 are accordingly moved into engagement with contacts I25 and I26 which it will be recalled is the high speed position for the motor. A circuit through the motor is established as follows: from line 1 through conductor I60, contact I33, switch bladi I 32, conductor I6I, contact 46, switch blade 41, conductor I62, contact I3I, switch blade I 30, conductor I59 to the switch blades I26 and 123, from switch blade I26, contact I 26, through conductor I15, high speed winding H5, and conductors I16 and I 62 to the line H. Current also flows from switch blade I23 through contact I25, conductor I11 through the high speed winding II6, condenser II1 and conductor I62 to the line H. Motor IIO now operates at high speed which causes circulation of unheated air through the system at a high rate of flow until bimetallic element 3I of thermostat 30 moves blades 32 and 33 to a position in which there is a call for heat or call for shut down of the circulation of unheated air,- in which position they are in engagement with contacts 34 and 35, respectively, Moving of the blades 32 and 33 in engagement with contacts 34 and 35 causes current to flow through relay coil H as previously described and causes switch blade 41 to move into engagementwith closed position the low speed motor circuit through this switch will be closed, this circuit being the same as that described in connection with the winter operation. It is therefore apparent that-if the temperature in the heating chamber for any reason is raised to a certain high value, motor H will be caused to operate regardless of the temperature surrounding thermostat 30, in the summer operation of the system.

It is thus seen that in the form of inventiondisclosed in Figure 2 I have provided a twospeed fan operation for winter time and means whereby the fan is operated at high speed in the summer when the cooling effect of unheated air is desirable, the operation of the fan in the summer time being entirely independent of the temperature in the heating chamber in normal op-. eration, but in which, should the temperature of the heating chamber be raised to a certain predetermined value, the fan will be operated to dissipate the heat in the furnace.

Having described the preferred embodiments of my invention it will be understood that it is capable of many modifications by those skilled in the art and I wish it to be understood that my invention is limited only by the scope of the appended claims.

I claim as my invention;

1. In a system of the class described, a heating chamber, means for increasing the heating effect of said chamber, air circulating means for circulating air through said chamber and through a space to be heated, temperature responsive means in said space, said temperature responsive means including a contact member movable in response to temperature changes in said space and fixed contact means cooperating therewith, said mov-.

able contact member and fixed contact means being arranged to engage one another upon the attainment of a predetermined low temperature in said space, a relay, means causing energization of said relay in response to engagement of said movable contact member and fixed contact means with one another, switching'means having two positions, means causing operation of said air circulating means in response to energization of said relay and the attainment of a high predetermined temperature in said chamber in one position of said switching means, means causing operation of said air circulating means when said relay is deenergized, regardless of the temperature of the heating chamber when the switching means is in a second position, and means independent of said relay for causing operation of said air circulating means upon the attainment of a high prede termined temperature in the heating chamber when the switching means is in the second position.

2. In an all year air conditioning control system, in combination, heating means, means comprising a fan for circulating air from said heating means to a space to be heated, a thermostat in said space, a relay controlled by said thermostat, switching-means responsive to heat generated at said heating means, means whereby said fan may be operated at variable speeds comprising electrical circuits controlled by said" switchmanner whereby it can only be completed to cause fan operation at relatively high speed when said thermostat is calling for heat, another of said circuits being such that it can be completed for fan operation at relatively low speed irrespective of the position of said relay, wherebyupon said thermostat becoming satisfied said fan will drop to relatively low speed, and said switching means can cause fan operation'at relatively low speed in response to heat at said heating means independently of thermostatic demands.

3. In an all year air conditioning control system, in combination, heating means, means comprising a fan for circulating air from said heating means to a space to be heated, a thermostat in said space, a relay controlled by said thermostat, switching means responsive to heat generated at said heating means, means whereby said fan may be operated at variable speeds comprising electrical circuits controlled by said switching means, one of said circuits controlling relatively high speed operation of said fan and said one circuit being controlled by said relay in a manner whereby it can only be completed to cause fan operation at relatively high speed Whensaid thermostat is calling for heat, another of said'circuits being such that it can be completed for fan operation at relatively low speed irrespective of the position of said relay, summer-winter switch means controlling electrical circuits whereby said relay relinquishes control of said heating means and whereby circuits are completed for operating said fan at relatively high speed whenever said relay is in a position indicating a demand for less heat at said thermostat.

4. In an all year air conditioning control system, in combination, heating means, means comprising a fan for circulating air from said heating means to a space to be heated, a thermostat in said space, a relay controlled by said thermostat, said relay having in and out positions and becoming energized at a predetermined temperature affecting said thermostat, switching means re-.

sponsive to heat generated at said heating means, means whereby said fan may be operated at variable speeds comprising electrical circuits controlled by said switching means, one of said circuits controlling relatively high speed fan operation and another controlling relatively low speed fan operation, said switching means causing said fan to start-after said relay has been operated in response to a demand for heat at said thermostat, and to thereafter automatically increase the speed of said fan, summer-winter switching means controlling electrical circuits so arranged that when said last means are in summer position circuits are completed for immediately causing high speed fan operation whenever said relay is in position indicating a demand for less heat at said thermostat, and said thermostat controlling operation of the relay in the same manner in summer as in winter.

5. In an "all year air conditioning control system, in combination, heating means, means for circulating air from the heating means to a space to be heated, control apparatus comprising a space thermostat having contacts which close at,

a predetermined temperature, a relay controlled by said thermostat and energizable when said contacts close, summer-winter switching means having summer and winter positions and controlling electrical circuits so arranged that in winter position of the switching means the relay controls the heating means and brings about increased air circulation when the relay is in one position, said switching means when in summer position causing said relay to relinquish control of said heating means, said contacts of said thermostat controlling said relay in the same manner in summer as in winter, said relay causing air circulation by said air circulating means when said relay is in its opposite position during summer operation, and means responsive to the temperature of the heating means operable to control the circulating means independently of the space thermostat and relay.

6. In an all year air conditioning control system, in combination, heating means, means for circulating air from the heating means to a space to be heated, control apparatus comprising a space thermostat having contacts which close at a predetermined temperature, a relay controlled by said thermostat and energizable when said contacts close, electrical circuit means controlling said heating means and air circulating means, summer-winter switching means having summer and winter positions controlling said circuit means, said relay when in one position controlling said circuit means to control the heating means providing said summer-winter switching means is in winter position and said relay when in said one position controlling said circuit means to control the air circulating means, said summerwinter switching means when in summer position said thermostat and energizable when said contacts close, electrical circuit means controlling said heating means and air circulating means, summer-winter switching means having summer and winter posit-ions controlling said circuit means, said relay when in one position controlling said circuit means to control the. heating means providing said summer-winter switching means is in winter position and said relay when in said one position controlling said circuit means to control the air circuialting means, said summer-winter switching means when in summer position aflecting said circuit means to interrupt control of the heating means (by said relay, said contacts of said thermostat controlling said relay in the same manner in summer as in winter, circuit means controlled by said relay and said summer-winter switching means so arranged that when the summer-winter switching means is in summer position the relay controls the air circulating means a to cause air circui-ation when the relay is in the afiecting said circuit means to interrupt control of the heating means by said relay, said contacts of said thermostat controlling said relay in the same manner in summer as in winter, and circuit means controlled by said relay and said summerwinter switching means so arranged that when the summer-winter switching means is in summer position the relay controls the air circulating means to cause air circulation when the relay is in the opposite position.

7; In an all year air conditioning control system, in combination, heating means, means for circulating air from the heating means to a space to be heated, control apparatus comprising a space thermostat having contacts-which close at a predetermined temperature, and a device responsive to the temperature of the heating means, a relay controlled by said thermostat and energizable when said contacts close, summer-winter switching means having summer and winter positions, electrical circuit means controlling said heating means and air circulating means, said summer-winter switching means controlling said circuit means and said device controlling saidcircuit means to control theheating means, said relay when in one position controlling said circuit means to control the heating means providing said summer-winter switching means is in winter position and dependently on said device, and said relay when in said one position controlling said circuit means to control the air circulating means, said summer-winter switching means when in summer [position an'ecting -said circuit means to interrupt control of the heating means by said relay, said contacts of said thermostat controlling said relay. in the same manner in summer as in winter,rand circuit means conswitching means so arranged that when the summer-winter switching means is in summer position the relay controls the air circulating means to cause air circulation when the relay is in the opposite position.

8. In an all year air conditioning control sys-.

tem, in combination, heating means, means for circulating air irom the heating means to a space to be heated, control apparatus comprising a space thermostat having contacts which close at a predetermined temperature, a relay controlled by in combination, heating means, meanscomprising a fan for circulating air from said heating. means to a space to be heated, a thermostat in said space, a relay controlled by said thermostat,

switching means responsive to heat generatedv at said heating means, means whereby said fan may be operatedalt variable speeds comprising electrical circuits controlled by said switching means, one of said circuits controlling relativelyhigh speed fan operation and another controlling relatively -:-low speed fan operation, connections whereby said relay normally controls said high speed circuit, connections whereby said switching means normally controls said low speed circuit independently of said relay, and means comprising a. summer-winter switch and connections whereby when said switch is in one position said switching means controls said high speed circuit independently of said relay.

-10. In an all year air conditioning control sys- .tem, in combination, heating means, means comprisinga fan for circulating air from said heating meansto a space to be heated, a thermostat in said space, a relay controlled by said thermostat, switching means responsive to heat generated atsaid heating means, means whereby said fan may beoperated at variable speeds comprising electrical "circuits controlled by said switching means, one circuits controlling rel-at-ively high speed operation and another controlling relatively lowsspeed fan operation, connections whereby saidrelay normally energizes said relay.

' GEORGE D. BOWER. 

